JP6991039B2 - Power supply and control system - Google Patents

Description

The present invention relates to a power feeding device and a control system.

An AC-DC adapter (hereinafter, also referred to as "AC adapter"), which is a power supply device that converts an AC voltage into a DC voltage, is known. For example, the AC adapter supplies power to an ONU (Optical Network Unit), which is a subscriber-side optical communication terminal included in a PON (Passive Optical Network) system.

AC adapters are classified into transformer type and switching type. Generally, it is possible to reduce the size by using the switching method, so the AC adapter that supplies power to the ONU adopts the switching method.

The operating principle of the switching type AC adapter will be described. In a switching AC adapter, a diode bridge and a first capacitor rectify and smooth the AC voltage and convert it to a DC voltage. After that, the switching element and the transformer convert the DC voltage into a high-frequency AC voltage. After that, the diode and the second capacitor rectify and smooth the high frequency AC voltage and convert it into a DC voltage.

A large-capacity aluminum electrolytic capacitor is adopted as the first capacitor and the second capacitor. However, in aluminum electrolytic capacitors, the pressure valve operates when the internal pressure rises due to deterioration over time. When the pressure valve is activated, the driving electrolytic solution in the aluminum electrolytic capacitor may leak to the outside of the aluminum electrolytic capacitor and adhere to other parts in the AC adapter. Other parts to which the driving electrolyte is attached are prone to failure. In addition, the AC adapter itself may fail due to the failure of other parts. Further, if the driving electrolyte causes a failure of a plurality of parts or a disconnection of the pattern of the substrate, it is difficult to repair the AC adapter.

Since the AC adapter is often used at the user's home, it is covered with a plastic housing in consideration of safety. Therefore, the user cannot confirm the degree of deterioration of the aluminum electrolytic capacitor from the appearance. Therefore, the user regularly replaces the AC adapter with a new one. However, depending on the individual difference of the AC adapter, the deterioration progresses quickly, and it may lead to a failure before replacement. In addition, since some users use the AC adapter beyond the product life of the AC adapter, the AC adapter may fail without being replaced.

A technique for determining the degree of deterioration of an aluminum electrolytic capacitor has been proposed (see, for example, Patent Document 1). For example, the AC adapter deterioration degree determination device of Patent Document 1 is installed outside the AC adapter and is connected to the AC adapter. The AC adapter deterioration degree determination device determines the deterioration degree of the AC adapter from the outside, and stores the determination result indicating the deterioration degree.

Japanese Unexamined Patent Publication No. 2016-20495

In the above technique, every time the deterioration degree of the AC adapter is determined, the AC adapter deterioration degree determination device must be connected to the AC adapter. Further, in the above technique, in order for the AC adapter to store the determination result indicating the degree of deterioration, a new component for acquiring and storing the determination result must be added inside the AC adapter. Further, the above technique only determines the degree of deterioration and does not prevent the AC adapter from failing.

An object of the present invention is to easily prevent a failure of a power feeding device at a low cost.

A power feeding device according to an aspect of the present invention is provided. The power feeding device includes a conversion unit that converts the first AC voltage into a first DC voltage by rectifying the first AC voltage, and a first that includes a ripple voltage by smoothing the first DC voltage. A smoothing unit that generates a DC voltage of 2 , a monitoring unit, a determination unit that determines the degree of deterioration of the smoothing unit, and an AC voltage input to the conversion unit are controlled based on the degree of deterioration. It has an input control unit and an input control unit. The monitoring unit has a maximum value detection unit that detects the maximum value of the second DC voltage from a preset period, and a minimum value that detects the minimum value of the second DC voltage from the period. Includes a detector. The maximum value detecting unit outputs a first comparison result obtained by comparing the maximum value of the second DC voltage with the maximum allowable value which is the maximum value of the allowable voltage range. The minimum value detection unit outputs a second comparison result obtained by comparing the minimum value of the second DC voltage with the allowable minimum value which is the minimum value of the allowable voltage range. The determination unit determines the degree of deterioration based on the first comparison result and the second comparison result.

According to the present invention, it is possible to easily prevent a failure of the power feeding device at a low cost.

It is a functional block diagram which shows the structure of the AC adapter of Embodiment 1. FIG. It is a figure which shows a part of the hardware which the AC adapter has. It is a graph which shows the relationship between voltage and time. It is a figure which shows the determination result table of Embodiment 1. FIG. It is a flowchart which shows the process which the AC adapter of Embodiment 1 performs. It is a functional block diagram which shows the structure of the AC adapter of Embodiment 2. It is a figure which shows the determination result table of Embodiment 2. It is a flowchart which shows the process which the AC adapter of Embodiment 2 performs. It is a functional block diagram which shows the structure of the AC adapter of Embodiment 3. It is a flowchart which shows the process which a cycle monitoring part executes. It is a flowchart which shows the process which ONU executes.

Hereinafter, embodiments will be described with reference to the drawings. The following embodiments are merely examples, and various modifications can be made within the scope of the present invention.

Embodiment 1.
FIG. 1 is a functional block diagram showing a configuration of an AC adapter which is a power feeding device according to the first embodiment. The AC adapter 100 converts an alternating current (AC: Alternating Current) voltage P0 into a direct current (DC: Direct Current) voltage P6. For example, the AC adapter 100 supplies a DC voltage P6 to an optical communication terminal such as an ONU.

The AC adapter 100 includes a conversion unit 110, a smoothing unit 120, a monitoring unit 130, a determination unit 140, an input control unit 150, and an amplifier 160.

Next, a part of the hardware of the AC adapter 100 will be described.
FIG. 2 is a diagram showing a part of the hardware included in the AC adapter. The AC adapter 100 includes a processor 101, a volatile storage device 102, and a non-volatile storage device 103.

The processor 101 is, for example, a CPU (Central Processing Unit), an FPGA (Field Programmable Gate Array), or the like. The volatile storage device 102 is the main storage device of the AC adapter 100. For example, the volatile storage device 102 is a RAM (Random Access Memory). The non-volatile storage device 103 is an auxiliary storage device of the AC adapter 100. For example, the non-volatile storage device 103 is an SSD (Solid State Drive) or the like.

The monitoring unit 130, the determination unit 140, and the input control unit 150 may be implemented by the processor 101. The monitoring unit 130, the determination unit 140, and the input control unit 150 may be mounted by a processing circuit.

Returning to FIG. 1, the functional block will be described.
The conversion unit 110 includes a diode bridge rectifying unit 111, a first smoothing capacitor 112, a voltage conversion unit 113, and a diode rectifying unit 114. The conversion unit 110 converts the AC voltage P1 input to the AC adapter 100 and supplied via the input control unit 150 into a DC voltage (that is, pulsating current voltage) P5 including an AC component of the AC voltage P1. do.

Next, the processes executed by the diode bridge rectifying unit 111, the first smoothing capacitor 112, the voltage conversion unit 113, and the diode rectifying unit 114 will be described in detail.

The diode bridge rectifying unit 111 rectifies the AC voltage P1 by changing the negative component of the AC voltage P1 to the positive component based on the characteristics of the bridge diode. The diode bridge rectifying unit 111 outputs a DC voltage (that is, pulsating current voltage) P2 including an AC component obtained after rectification to the first smoothing capacitor 112.

The first smoothing capacitor 112 smoothes the DC voltage P2 and outputs the DC voltage P3 based on the characteristic of accumulating electric charges. The first smoothing capacitor 112 outputs the DC voltage P3 to the voltage conversion unit 113.

The voltage conversion unit 113 includes a switching element and a transformer. The voltage conversion unit 113 converts the DC voltage P3 into a high-frequency AC voltage P4. The voltage conversion unit 113 outputs a high-frequency AC voltage P4 to the diode rectification unit 114.

The diode rectifying unit 114 removes the negative component of the high frequency AC voltage P4 based on the characteristics of the diode. That is, the diode rectifying unit 114 rectifies the high frequency AC voltage P4. The diode rectifying unit 114 outputs the DC voltage P5 obtained by rectifying the high-frequency AC voltage P4 to the smoothing unit 120.

The smoothing unit 120 includes a second smoothing capacitor 121. The smoothing unit 120 smoothes the DC voltage P5, which is the pulsating current voltage supplied from the conversion unit 110, to generate a smoothed DC voltage P6. The process executed by the second smoothing capacitor 121 will be described in detail.

The second smoothing capacitor 121 generates a smoothed DC voltage P6 from the DC voltage P5 which is the pulsating voltage output by the diode rectifying unit 114 based on the characteristic of accumulating electric charges. The smoothed DC voltage P6 includes a ripple voltage. The second smoothing capacitor 121 outputs a smoothed DC voltage P6. For example, the second smoothing capacitor 121 outputs the smoothed DC voltage P6 to the ONU.

The monitoring unit 130 monitors the DC voltage P6 including the ripple voltage. Further, the monitoring unit 130 includes a maximum value detection unit 131 and a minimum value detection unit 132. For example, the maximum value detection unit 131 and the minimum value detection unit 132 may be mounted by a voltage monitoring IC such as a reset IC (Integrated Circuit). The functions of the maximum value detection unit 131 and the minimum value detection unit 132 will be described in detail later.

The determination unit 140 determines the degree of deterioration of the smoothing unit 120 (that is, the degree of deterioration of the second smoothing capacitor 121). The function of the determination unit 140 will be described in detail later.

The input control unit 150 controls the AC voltage input to the conversion unit 110 based on the determination result of the determination unit 140. The function of the input control unit 150 will be described in detail later.
The amplifier 160 amplifies the DC voltage P6. The amplifier 160 will be described in detail later. The amplifier 160 may not be included in the AC adapter 100.

FIG. 3 is a graph showing the relationship between voltage and time. The vertical direction of the graph shown in FIG. 3 indicates a voltage. The horizontal axis of the graph shown in FIG. 3 indicates time. Let E ₀ be a voltage value which is a representative value (for example, an average value or a median value) of a DC voltage P6 including a ripple voltage output from the second smoothing capacitor 121. The waveform 400 shows a DC voltage P6 including a ripple voltage. In FIG. 3, the peak value of the DC voltage P6 including the ripple voltage is represented by Epp.

The waveform 401 shows a DC voltage P2 which is a pulsating current voltage output from the diode bridge rectifying unit 111.

The straight line 402 and the straight line 403 indicate the allowable voltage range of the peak peak value Epp. That is, the straight line 402 indicates the maximum allowable value, which is the maximum value in the allowable voltage range. For example, the maximum allowable value is set to be larger than the voltage value E ₀ . The straight line 403 indicates the allowable minimum value which is the minimum value in the allowable voltage range. For example, the allowable minimum value is set to a value smaller than the voltage value E ₀ .

The smoothing ability of the second smoothing capacitor 121 decreases when the capacitance of the second smoothing capacitor 121 decreases due to aged deterioration or the like. The peak peak value Epp of the ripple voltage becomes large when the smoothing ability of the second smoothing capacitor 121 decreases. There is a correlation between the degree of deterioration of the second smoothing capacitor 121, the capacitance of the second smoothing capacitor 121, and the peak peak value Epp. Therefore, the allowable voltage range according to the degree of deterioration can be calculated by simulation. The allowable voltage range is stored in advance in the volatile storage device 102 or the non-volatile storage device 103. Alternatively, the permissible voltage range is electrically detected using the characteristics of the power supply monitoring IC.

FIG. 4 is a diagram showing a determination result table of the first embodiment. The determination result table 104 is stored in the volatile storage device 102 or the non-volatile storage device 103. The determination result table 104 includes input information, output information, and determination result items. The input information A is information input from the maximum value detection unit 131 to the determination unit 140. The input information B is information input from the minimum value detection unit 132 to the determination unit 140. The output information C is information output by the determination unit 140. The determination unit 140 generates output information C based on the input information A and B. The output information C is input to the input control unit 150. The input information A, the input information B, and the output information C are shown in FIG.

The monitoring unit 130 monitors the DC voltage P6 including the ripple voltage for a preset period. The maximum value detection unit 131 and the minimum value detection unit 132 detect the maximum value and the minimum value of the DC voltage P6 including the ripple voltage from the period. The maximum value is one peak voltage having the maximum voltage, but may be a representative value (for example, an average value) of a plurality of peak voltages. The minimum value is one bottom voltage having the minimum voltage, but may be a representative value (for example, an average value) of a plurality of bottom voltages.

Further, depending on the internal configuration of the AC adapter 100, the peak peak value Epp may be very small, and it may be difficult to detect the maximum value and the minimum value of the DC voltage P6 including the ripple voltage. In such a case, for example, an amplifier 160 such as an operational amplifier is installed inside the AC adapter 100. The maximum value detection unit 131 and the minimum value detection unit 132 can detect the maximum value and the minimum value of the DC voltage P6 by amplifying the DC voltage P6 including the ripple voltage by the amplifier 160. Further, when the maximum value detection unit 131 and the minimum value detection unit 132 amplify the DC voltage P6 including the ripple voltage at a certain amplification factor, for example, the maximum value detection unit 131 expands the allowable voltage range according to the amplification factor of the DC voltage P6. May be good.

When the maximum value of the DC voltage P6 including the ripple voltage is equal to or less than the allowable maximum value (straight line 402 in the case of FIG. 3), the maximum value detecting unit 131 inputs the input information A in which the Low level (that is, “0”) is set. Output to the determination unit 140. Further, when the maximum value of the DC voltage P6 including the ripple voltage is larger than the allowable maximum value, the maximum value detection unit 131 outputs the input information A for which the High level (that is, “1”) is set to the determination unit 140.

When the minimum value of the DC voltage P6 including the ripple voltage is equal to or higher than the allowable minimum value (straight line 403 in the case of FIG. 3), the minimum value detection unit 132 inputs the input information B for which the High level (that is, “1”) is set. Output to the determination unit 140. Further, when the minimum value of the DC voltage P6 including the ripple voltage is smaller than the minimum value in the allowable voltage range, the minimum value detection unit 132 uses the input information B for which the Low level (that is, “0”) is set to the determination unit 140. Output.

The determination unit 140 determines the degree of deterioration of the smoothing unit 120 based on the comparison result of comparing the DC voltage P6 including the ripple voltage with the allowable voltage range. That is, the determination unit 140 determines the degree of deterioration of the second smoothing capacitor 121 based on the input information A and the input information B. For example, the determination unit 140 can determine the degree of deterioration of the second smoothing capacitor 121 by using the determination result table 104.

When the input information A is "0" and the input information B is "0", the determination unit 140 determines that the second smoothing capacitor 121 is slightly deteriorated. The determination unit 140 sets the determination result in the output information C. For example, the determination unit 140 sets “0” in the output information C as the determination result. The determination unit 140 outputs the output information C to the input control unit 150.

When the input information A is "1" and the input information B is "0", the determination unit 140 determines that the second smoothing capacitor 121 has deteriorated. The determination unit 140 sets the determination result in the output information C. For example, the determination unit 140 sets “1” in the output information C as the determination result. The determination unit 140 outputs the output information C to the input control unit 150.

When the input information A is "0" and the input information B is "1", the determination unit 140 determines that the second smoothing capacitor 121 is normal. The determination unit 140 sets the determination result in the output information C. For example, the determination unit 140 sets “0” in the output information C as the determination result. The determination unit 140 outputs the output information C to the input control unit 150.

When the input information A is "1" and the input information B is "1", the determination unit 140 determines that the second smoothing capacitor 121 is slightly deteriorated. The determination unit 140 sets the determination result in the output information C. For example, the determination unit 140 sets “0” in the output information C as the determination result. The determination unit 140 outputs the output information C to the input control unit 150.
In this way, the determination unit 140 can determine the degree of deterioration of the second smoothing capacitor 121 based on the input information A and the input information B.

The input control unit 150 controls the AC voltage input to the conversion unit 110 based on the degree of deterioration. The function of the input control unit 150 will be described in detail. When the output information C indicates "1", the input control unit 150 cuts off the input of the AC voltage by using the switch function or the fuse. The input control unit 150 may be a means for cutting off the power supply path immediately before the diode bridge rectifying unit 111, the first smoothing capacitor 112, or the diode rectifying unit 114. In this way, the input control unit 150 can stop the operation of the AC adapter 100 by cutting off the power supply path.

Next, the process executed by the AC adapter 100 will be described with reference to the flowchart.
FIG. 5 is a flowchart showing a process executed by the AC adapter of the first embodiment.
(Step S11) The monitoring unit 130 monitors the DC voltage P6 including the ripple voltage for a preset period.

(Step S12) The maximum value detection unit 131 detects the maximum value of the DC voltage P6 including the ripple voltage from a preset period. The maximum value detection unit 131 determines whether or not the maximum value of the DC voltage P6 including the ripple voltage is equal to or greater than the allowable maximum value. The maximum value detection unit 131 sets the determination result in the input information A. The maximum value detection unit 131 outputs the input information A to the determination unit 140.

The minimum value detection unit 132 detects the minimum value of the DC voltage P6 including the ripple voltage from the preset period. The minimum value detection unit 132 determines whether or not the minimum value of the DC voltage P6 including the ripple voltage is equal to or less than the allowable minimum value. The minimum value detection unit 132 sets the determination result in the input information B. The minimum value detection unit 132 outputs the input information B to the determination unit 140.

(Step S13) The determination unit 140 determines the degree of deterioration of the second smoothing capacitor 121 based on the input information A and the input information B.

(Step S14) The determination unit 140 sets the determination result based on the degree of deterioration in the output information C. The determination unit 140 outputs the output information C to the input control unit 150.

(Step S15) The input control unit 150 determines whether or not the second smoothing capacitor 121 has deteriorated. That is, the input control unit 150 determines whether or not the output information C indicates “1”.
When the second smoothing capacitor 121 is deteriorated (Yes in step S15), the input control unit 150 advances the process to step S16. When the second smoothing capacitor 121 has not deteriorated (No in step S15), the input control unit 150 ends the process.

(Step S16) The input control unit 150 cuts off the input of the AC voltage by using the switch function or the fuse.

The AC adapter 100 determines the degree of deterioration inside the AC adapter 100. Therefore, the user does not have to install a device for determining the degree of deterioration outside the AC adapter 100 each time the degree of deterioration of the AC adapter 100 is determined. That is, the degree of deterioration can be easily measured without imposing a burden on the user.

The deterioration degree information is not stored outside the AC adapter 100, but is stored inside the AC adapter 100. Therefore, the AC adapter 100 does not need to newly add a component for acquiring the degree of deterioration inside the AC adapter 100. Therefore, the AC adapter 100 can be realized at a low cost.

Since the AC adapter 100 cuts off the input of the AC voltage P1 when the second smoothing capacitor 121 is deteriorated, it prevents the state of the second smoothing capacitor 121 from being deteriorated. The AC adapter 100 can prevent the driving electrolytic solution in the second smoothing capacitor 121 from leaking to the outside by preventing the state of the second smoothing capacitor 121 from deteriorating. Since the AC adapter 100 can prevent the driving electrolytic solution in the second smoothing capacitor 121 from leaking to the outside, it is possible to prevent the AC adapter 100 from failing.
Therefore, according to the first embodiment, the AC adapter 100 can easily prevent the AC adapter 100 from failing at a low cost.

Embodiment 2.
Next, the second embodiment will be described. The matters different from those of the first embodiment will be mainly described, and the common matters will be omitted.
When the second smoothing capacitor 121 is deteriorated, the AC adapter 100 of the first embodiment cuts off the input of the AC voltage P1 to the conversion unit 110 to prevent the AC adapter 100 from failing. In the AC adapter 100a of the second embodiment, the degree of deterioration of the second smoothing capacitor 121 is confirmed step by step.

FIG. 6 is a functional block diagram showing the configuration of the AC adapter according to the second embodiment. The AC adapter 100a includes a determination unit 140a, a notification control unit 170, and an LED 171. The configuration of FIG. 6, which is the same as or corresponds to the configuration shown in FIG. 1, has the same reference numerals as those shown in FIG. In the second embodiment, FIGS. 1 to 3 are referred to.

The determination unit 140a notifies the notification control unit 170 of the degree of deterioration of the second smoothing capacitor 121. The notification control unit 170 lights the LED 171 based on the degree of deterioration of the second smoothing capacitor 121. The notification control unit 170 may be mounted on the processor 101. The notification control unit 170 may be mounted by a processing circuit.

FIG. 7 is a diagram showing a determination result table of the second embodiment. The determination result table 104a is stored in the volatile storage device 102 or the non-volatile storage device 103. The determination result table 104a includes input information, output information, and determination result items. The input information A is information input from the maximum value detection unit 131 to the determination unit 140a. The input information B is information input from the minimum value detection unit 132 to the determination unit 140a. The output information C is information output by the determination unit 140a. The output information D is information output by the determination unit 140a. The output information D is input to the notification control unit 170.
The determination unit 140a determines the degree of deterioration of the second smoothing capacitor 121 based on the input information A and the input information B.

When the input information A is "0" and the input information B is "0", the determination unit 140a determines that the second smoothing capacitor 121 is slightly deteriorated. The determination unit 140 sets the determination result in the output information C. For example, the determination unit 140a sets "0" in the output information C as the determination result. The determination unit 140a outputs the output information C to the input control unit 150. The determination unit 140 sets the determination result in the output information D. For example, the determination unit 140a sets "1" in the output information D as the determination result. The determination unit 140a outputs the output information D to the notification control unit 170.

When the input information A is 1 and the input information B is "0", the determination unit 140a determines that the second smoothing capacitor 121 has deteriorated. The determination unit 140 sets the determination result in the output information C. For example, the determination unit 140a sets "1" in the output information C as the determination result. The determination unit 140a outputs the output information C to the input control unit 150. The determination unit 140 sets the determination result in the output information D. For example, the determination unit 140a sets “0” in the output information D as the determination result. The determination unit 140a outputs the output information D to the notification control unit 170.

When the input information A is "0" and the input information B is "1", the determination unit 140a determines that the second smoothing capacitor 121 is normal. The determination unit 140 sets the determination result in the output information C. For example, the determination unit 140a sets "0" in the output information C as the determination result. The determination unit 140a outputs the output information C to the input control unit 150. The determination unit 140 sets the determination result in the output information D. For example, the determination unit 140a sets “0” in the output information D as the determination result. The determination unit 140a outputs the output information D to the notification control unit 170.

When the input information A is "1" and the input information B is "1", the determination unit 140a determines that the second smoothing capacitor 121 is slightly deteriorated. The determination unit 140 sets the determination result in the output information C. For example, the determination unit 140a sets "0" in the output information C as the determination result. The determination unit 140a outputs the output information C to the input control unit 150. The determination unit 140 sets the determination result in the output information D. For example, the determination unit 140a sets "1" in the output information D as the determination result. The determination unit 140a outputs the output information D to the notification control unit 170.

When the output information D is 1, the notification control unit 170 lights the LED 171. That is, the notification control unit 170 turns on the LED 171 when the second smoothing capacitor 121 is slightly deteriorated.

Next, the process executed by the AC adapter 100a will be described with reference to the flowchart.
FIG. 8 is a flowchart showing a process executed by the AC adapter of the second embodiment.
(Step S21) The monitoring unit 130 monitors the DC voltage P6 including the ripple voltage for a preset period.

(Step S22) The maximum value detection unit 131 detects the maximum value of the DC voltage P6 including the ripple voltage from a preset period. The maximum value detection unit 131 determines whether or not the maximum value of the DC voltage P6 including the ripple voltage is equal to or greater than the maximum value in the allowable voltage range. The maximum value detection unit 131 sets the determination result in the input information A. The maximum value detection unit 131 outputs the input information A to the determination unit 140a.

The minimum value detection unit 132 detects the minimum value of the DC voltage P6 including the ripple voltage from the preset period. The minimum value detection unit 132 determines whether or not the minimum value of the DC voltage P6 including the ripple voltage is equal to or less than the minimum value in the allowable voltage range. The minimum value detection unit 132 sets the determination result in the input information B. The minimum value detection unit 132 outputs the input information B to the determination unit 140a.

(Step S23) The determination unit 140a determines the degree of deterioration of the second smoothing capacitor 121 based on the input information A and the input information B.

(Step S24) The determination unit 140a sets the determination result in the output information D. The determination unit 140a outputs the output information D to the notification control unit 170.
Further, the determination unit 140a sets the determination result in the output information C. The determination unit 140a outputs the output information C to the input control unit 150. When the output information C indicates 1, the input control unit 150 cuts off the input of the AC voltage.

(Step S25) The notification control unit 170 determines whether or not the second smoothing capacitor 121 is slightly deteriorated. That is, the notification control unit 170 determines whether or not the output information D indicates 1.
When the second smoothing capacitor 121 is slightly deteriorated (Yes in step S25), the notification control unit 170 advances the process to step S26. When the second smoothing capacitor 121 is not slightly deteriorated (No in step S25), the notification control unit 170 ends the process.

(Step S26) The notification control unit 170 lights the LED 171.
As a result, the user can recognize that the second smoothing capacitor 121 is slightly deteriorated by visually recognizing the lighting of the LED 171. Further, since the AC adapter 100a recognizes that the user has slightly deteriorated, the AC adapter 100a prompts the replacement before the operation of the AC adapter 100a is stopped, so that the failure of the AC adapter 100a can be prevented.

The monitoring unit 130, the determination unit 140a, the notification control unit 170, and the LED 171 may be installed in an external device provided at the output end of the AC adapter 100a. As a result, the external device can determine the degree of deterioration of the second smoothing capacitor 121 outside the AC adapter 100a. The notification control unit 170 included in the external device turns on the LED 171 when the second smoothing capacitor 121 is deteriorated. The notification control unit 170 changes the lighting color of the LED 171 when the second smoothing capacitor 121 is deteriorated and when it is slightly deteriorated.

The notification control unit 170 may blink the LED 171 when the second smoothing capacitor 121 is slightly deteriorated. When the second smoothing capacitor 121 is slightly deteriorated, the notification control unit 170 may notify by voice. For example, the notification control unit 170 generates a warning sound when the second smoothing capacitor 121 is slightly deteriorated. In this case, the LED 171 is changed to a speaker.

When the second smoothing capacitor 121 is slightly deteriorated, the notification control unit 170 may indicate on the display installed in the AC adapter 100a that the second smoothing capacitor 121 is slightly deteriorated. good. In this case, the LED 171 is changed to a display.
According to the second embodiment, the AC adapter 100a is a notification device such as an LED 171 and outputs notification information for the user to recognize that the second smoothing capacitor 121 is slightly deteriorated. The notification device is, for example, an LED 171, a speaker, a display, or the like. The broadcast information is output by light, sound, image display, vibration, radio wave transmission, and the like.

Embodiment 3.
Next, the third embodiment will be described. The matters different from those of the second embodiment will be mainly described, and the common matters will be omitted.
In the AC adapter 100a of the second embodiment, the LED 171 was turned on when the second smoothing capacitor 121 was slightly deteriorated. However, if the user does not check the LED 171 the user may not notice that the second smoothing capacitor 121 has slightly deteriorated. The AC adapter 100b of the third embodiment notifies the administrator that the second smoothing capacitor 121 has slightly deteriorated. Further, the management terminal 300 stops the operation of the AC adapter 100b.

FIG. 9 is a functional block diagram showing the configuration of the AC adapter according to the third embodiment. The AC adapter 100b is connected to the ONU200. The AC adapter 100b supplies a DC voltage to the ONU 200. Further, the ONU 200 is connected to the management terminal 300. The ONU200 is also referred to as a first device. The management terminal 300 is also referred to as a second device.

The AC adapter 100b has a determination unit 140b and a cycle monitoring unit 180. The configuration of FIG. 9, which is the same as or corresponds to the configuration shown in FIGS. 1 and 6, is designated by the same reference numerals as those shown in FIGS. 1 and 6. In the third embodiment, FIGS. 1 to 3, 6 and 7 are referred to.

The determination unit 140b determines the degree of deterioration of the second smoothing capacitor 121 based on the input information A and the input information B. The input information A and the input information B are the information output by the maximum value detection unit 131 and the minimum value detection unit 132.
The determination unit 140b outputs the output information C in which the determination result is set to the input control unit 150. The determination unit 140b outputs the output information D in which the determination result is set to the notification control unit 170. The determination unit 140b transmits the output information E in which the determination result is set to the cycle monitoring unit 180. The determination unit 140b is the same as the determination unit 140a except for the process of notifying the cycle monitoring unit 180 of the determination result.

The periodic monitoring unit 180 periodically transmits the determination result to the ONU 200. For example, the periodic monitoring unit 180 periodically transmits the determination result to the ONU 200 by using the USB (Universal Serial Bus) interface. The periodic monitoring unit 180 may be mounted on the processor 101. The cycle monitoring unit 180 may be mounted by a processing circuit.

The ONU 200 has a deterioration monitoring unit 210 and a transmission / reception unit 220. For example, the deterioration monitoring unit 210 is connected to the periodic monitoring unit 180 by using a USB interface. The deterioration monitoring unit 210 transmits the determination result received from the periodic monitoring unit 180 to the transmission / reception unit 220. The transmission / reception unit 220 transmits the determination result to the management terminal 300. When the deterioration monitoring unit 210 and the transmission / reception unit 220 receive the cutoff command F of the AC adapter 100b from the management terminal 300, the input control unit 150 causes the input control unit 150 to cut off the AC voltage input to the conversion unit 110.
The deterioration monitoring unit 210 and the transmission / reception unit 220 may be mounted by the processor of the ONU 200. The deterioration monitoring unit 210 and the transmission / reception unit 220 may be mounted by a processing circuit.

Next, the process executed by the periodic monitoring unit 180 will be described with reference to the flowchart.
FIG. 10 is a flowchart showing a process executed by the periodic monitoring unit.

(Step S31) The cycle monitoring unit 180 receives the output information E in which the determination result is set from the determination unit 140b. The determination result indicates the degree of deterioration (that is, normal, light deterioration, or deterioration) of the second smoothing capacitor 121.

(Step S32) The periodic monitoring unit 180 transmits the determination result to the ONU 200.

(Step S33) The cycle monitoring unit 180 determines whether or not the cutoff command F has been received from the ONU 200. When the cutoff command F is received (Yes in step S33), the cycle monitoring unit 180 advances the process to step S34. If the cutoff command F has not been received (No in step S33), the cycle monitoring unit 180 ends the process.

(Step S34) The cycle monitoring unit 180 transmits the cutoff instruction signal G to the input control unit 150. The input control unit 150 cuts off the AC voltage input to the conversion unit 110 by using a switch function or a fuse based on the cutoff instruction signal (G). As a result, the input control unit 150 stops the operation of the AC adapter 100b.

Next, the process executed by the ONU 200 will be described using a flowchart.
FIG. 11 is a flowchart showing a process executed by the ONU.
(Step S41) The deterioration monitoring unit 210 receives the determination result from the AC adapter 100b.

(Step S42) The deterioration monitoring unit 210 requests the transmission / reception unit 220 to transmit the determination result.

(Step S43) The transmission / reception unit 220 transmits the determination result to the management terminal 300. As a result, the administrator using the management terminal 300 can confirm the degree of deterioration of the second smoothing capacitor 121.

(Step S44) The transmission / reception unit 220 determines whether or not the cutoff command F has been received from the management terminal 300. When the cutoff command F is received (Yes in step S44), the transmission / reception unit 220 advances the process to step S45. If the cutoff command F has not been received (No in step S44), the transmission / reception unit 220 ends the process.

(Step S45) The transmission / reception unit 220 requests the deterioration monitoring unit 210 to transmit the cutoff command F.

(Step S46) The deterioration monitoring unit 210 transmits the cutoff command F to the AC adapter 100b.

For example, the administrator who uses the management terminal 300 visually recognizes the determination result and recognizes that the second smoothing capacitor 121 is slightly deteriorated. The management terminal 300 stops the operation of the AC adapter 100b via the ONU 200. As a result, the remote administrator can stop the operation of the AC adapter 100b.

According to the third embodiment, the AC adapter 100b can notify the management terminal 300 of the degree of deterioration of the second smoothing capacitor 121 via the ONU 200. Further, the management terminal 300 can stop the operation of the AC adapter 100b via the ONU 200.

The features of each of the embodiments described above can be appropriately combined with each other.

100, 100a, 100b AC adapter (feeding device), 110 converter, 111 diode bridge rectifier, 112 first smoothing capacitor, 113 voltage converter, 114 diode rectifier, 120 smoother, 121 second smoother Capacitor, 130 monitoring unit, 131 maximum value detection unit, 132 minimum value detection unit, 140, 140a, 140b judgment unit, 150 input control unit, 160 amplifier, 170 notification control unit, 171 LED (notification device), 180 cycle monitoring Unit, 200 ONU (first device), 210 deterioration monitoring unit, 220 transmission / reception unit, 300 management terminal (second device)

Claims (10)

A conversion unit that converts the first AC voltage into a first DC voltage by rectifying the first AC voltage, and
A smoothing unit that generates a second DC voltage including a ripple voltage by smoothing the first DC voltage.
With the monitoring department
A determination unit that determines the degree of deterioration of the smoothing unit, and a determination unit.
An input control unit that controls the AC voltage input to the conversion unit based on the degree of deterioration.
Have,
The monitoring unit
A maximum value detector that detects the maximum value of the second DC voltage from a preset period, and
Includes a minimum value detection unit that detects the minimum value of the second DC voltage from the period.
The maximum value detecting unit outputs a first comparison result obtained by comparing the maximum value of the second DC voltage with the maximum allowable value which is the maximum value of the allowable voltage range.
The minimum value detection unit outputs a second comparison result obtained by comparing the minimum value of the second DC voltage with the allowable minimum value which is the minimum value of the allowable voltage range.
The determination unit determines the degree of deterioration based on the first comparison result and the second comparison result.
Power supply device. In the determination unit, when the maximum value of the second DC voltage is larger than the allowable maximum value and the minimum value of the second DC voltage is smaller than the allowable minimum value, the smoothing unit deteriorates. Judging that it is
When it is determined that the smoothing unit is deteriorated, the input control unit cuts off the AC voltage input to the conversion unit.
The power supply device according to claim 1 . Has more amplifiers
The amplifier amplifies the second DC voltage and
The maximum value detecting unit detects the maximum value of the second DC voltage from the amplified second DC voltage.
The minimum value detection unit detects the minimum value of the second DC voltage from the amplified second DC voltage.
The power supply device according to claim 1 . It also has a notification control unit and a notification device.
When only one of the maximum value of the second DC voltage and the minimum value of the second DC voltage is out of the allowable voltage range, the notification control unit causes the notification device to output notification information.
The power supply device according to claim 1 . Further having a periodic monitoring unit for periodically transmitting the degree of deterioration to the first device.
The power feeding device according to any one of claims 1 to 4 . When the cycle monitoring unit receives a cutoff command for cutting off the AC voltage input to the conversion unit from the first device, the cycle monitoring unit transmits a cutoff instruction signal to the input control unit.
The input control unit cuts off the AC voltage input to the conversion unit based on the cutoff instruction signal.
The power feeding device according to claim 5 . The first device is a device to which the second DC voltage is supplied.
The power feeding device according to claim 5 or 6 . Power supply device and
The first device and
Have,
The power feeding device is
A conversion unit that converts the first AC voltage into a first DC voltage by rectifying the first AC voltage, and
A smoothing unit that generates a second DC voltage including a ripple voltage by smoothing the first DC voltage.
With the monitoring department
A determination unit that determines the degree of deterioration of the smoothing unit, and a determination unit.
An input control unit that controls the AC voltage input to the conversion unit based on the degree of deterioration.
Equipped with
The monitoring unit
A maximum value detector that detects the maximum value of the second DC voltage from a preset period, and
Includes a minimum value detection unit that detects the minimum value of the second DC voltage from the period.
The maximum value detecting unit outputs a first comparison result obtained by comparing the maximum value of the second DC voltage with the maximum allowable value which is the maximum value of the allowable voltage range.
The minimum value detection unit outputs a second comparison result obtained by comparing the minimum value of the second DC voltage with the allowable minimum value which is the minimum value of the allowable voltage range.
The determination unit determines the degree of deterioration based on the first comparison result and the second comparison result.
Control system. The power feeding device further includes a periodic monitoring unit that periodically transmits the degree of deterioration to the first device.
The control system according to claim 8 . The first device transmits the degree of deterioration to the second device.
The control system according to claim 8 or 9 .

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